Abstract: A hydrogen gas storage and supply method including: (a) providing a chamber and, contained therein, a plurality of shell-core micro-spheres, each comprising a shell and a hollow or porous core, filled with pressurized hydrogen gas at an internal pressure P; and (b) heating the micro-spheres to a temperature T to reduce the shell tensile strength ?t to an extent that a tensile stress ? experienced by a shell of the micro-spheres meets the condition of ????t, causing hydrogen to diffuse out of the micro-spheres to provide hydrogen fuel from the chamber to a hydrogen-consuming device, where the material-specific parameter ? has a value between 0.3 and 0.7. The shell stress scales with the internal hydrogen gas pressure and the tensile strength ?t decreases with increasing micro-sphere temperature. For instance, this condition is met when the micro-spheres are heated to a temperature within the range of [Tg?25° C.] to [Tg+25° C.

Abstract: A direct write or freeform fabrication apparatus and process for making a device or a three-dimensional object. By way of example the method comprises: (a) providing a target surface on an object-supporting platform; (b) operating a material deposition sub-system comprising a liquid deposition device for dispensing at least a liquid composition and a solid powder-dispensing device for dispensing solid powder particles to selected locations on the target surface; (c) operating a directed energy source for supplying energy to the dispensed liquid composition and the dispensed powder particles to induce a chemical reaction or physical transition thereof at the selected locations; and (d) moving the deposition sub-system and the object-supporting platform relative to one another in a plane defined by first and second directions to form the dispensed liquid composition and the dispensed powder particles into the device or object. An apparatus is also provided for carrying out this process.

Abstract: A method for the preparation of a monolayer of meso-scaled particles within a size range of one nanometer to several hundreds of microns. The method includes the steps of (A) providing a thin liquid film onto an external surface of a rotary member; (B) dispensing meso-scaled particles at a desired rate onto an external surface of the thin liquid film so as to position the particles at a gas-liquid interface; (C) forming a uniform monolayer of the particles on the gas-liquid interface; and (D) transferring the monolayer from the gas-liquid interface to a solid substrate. Monolayers of meso-scaled particles on solid surfaces are useful in many areas of science and technology, including functional coatings that modify the physical and chemical properties of the underlying surfaces. The method is particularly useful for the preparation of catalyzed proton exchange membranes for fuel cell applications.

Abstract: A process for producing nano-scaled graphene plates with each plate comprising a sheet of graphite plane or multiple sheets of graphite plane with the graphite plane comprising a two-dimensional hexagonal structure of carbon atoms. The process includes the primary steps of: (a) providing a powder of fine graphite particles comprising graphite crystallites with each crystallite comprising one sheet or normally a multiplicity of sheets of graphite plane bonded together; (b) exfoliating the graphite crystallites to form exfoliated graphite particles, which are characterized by having at least two graphite planes being either partially or fully separated from each other; and (c) subjecting the exfoliated graphite particles to a mechanical attrition treatment to further reduce at least one dimension of the particles to a nanometer scale, <100 nm, for producing the nano-scaled graphene plates.

Abstract: An open, liquid-state electrochemical cell that can be used as a primary or rechargeable power source for various miniaturized or portable electronic devices. The cell is composed of flexible and thin layers of anode, cathode and electrolyte materials with the electrolyte layer being exposed to open air. The electrolyte with an open configuration avoids the accumulation of gases upon storage of the cell. The electrolyte includes (a) a deliquescent material for keeping the open cell wet at all times and (b) an ion conductive material for transporting ions across the electrolyte layer. The electrolyte does not include a water-soluble polymer. The invention also provides a multi-cell battery that contains cells exhibiting the above-described features. The cell or battery, along with an electronic component, may be attached to a flexible substrate to make a functional device.

Abstract: A direct-write micro- or nano-lithography method for depositing a functional material with a preferred orientation onto a target surface. The method includes the steps of (1) forming a precursor fluid to the functional material; (2) operating a sub-micrometer tip to discharge, on contact, the precursor fluid onto the target surface so as to produce a desired pattern of deposited functional material in sub-micrometer dimensions; and (3) during the pattern-producing step, subjecting the deposited material to a highly localized electric or magnetic field for attaining a preferred orientation in at least a portion of the functional material. The method is particularly useful for microfabrication, nanotechnology, and molecular electronics.

Abstract: A twin-wire arc deposition method for depositing a nano-structured catalyst coating onto a solid electrolyte membrane or an electrode substrate from a precursor catalyst material selected from the group consisting of a metal, metal alloy, metal compound, and ceramic material.

Abstract: A photo-electrolytic catalyst system which comprises two materials: (a) a semiconductor material with a non-zero energy gap Eg which, in response to an incident radiation having an energy greater than Eg, generates electron-hole pairs as charge carriers; and (b) a facilitating material in electronic contact with the semiconductor material to facilitate separation of the radiation-generated electrons from the holes to reduce the probability of charge carrier recombinations The catalyst makes use of both majority and minority charge carriers to promote photo-electrolysis reactions for producing hydrogen directly from water or an aqueous electrolyte at higher rates and improved efficiencies.

Abstract: A self-moisturizing polymer electrolyte membrane (PEM) composition, a membrane-electrode assembly, and a fuel cell. The PEM composition comprises (a) a proton-conducting polymer containing a detachable hydrogen ion and a counter-ion bonded to the polymer; and (b) a deliquescent material for keeping the membrane wet and for detaching the hydrogen ion to facilitate proton transport in the membrane. Alternatively, the deliquescent material may be strategically located on the gas flow field channels, gas-diffusion electrode or backing layers, and/or electro-catalyst layers. A preferred PEM polymer is poly(perfluoro sulfonic acid). This self-moisturizing PEM obviates the need to have a pre-humidifying structure or a complex flow field design in a fuel cell.

Abstract: An apparatus for cutting a scrap tire includes a base with a top face, a vertical shaft mounted on the base, a tire support mounted rotatably on the vertical shaft, and first and second cutting units. The first cutting unit is mounted on the base and is adapted to cut the scrap tire along a first plane that is parallel to the top face of the base. The second cutting unit is mounted on the base and is adapted to cut the scrap tire along a second plane that is perpendicular to the top face of the base.